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1. Influence of yaw misalignment on the propagation of Tidal Turbine wake

   Modali, Pranav K; Banerjee, Arindam (September 2019, 13th European Wave and Tidal Energy Conference, Napoli, Italy)

   A yaw misalignment to the inflow for tidal current turbines are known to result in performance degradation and deflection of the downstream wake. A comprehensive analysis of the wake behavior under yaw is thus essential to provide insights to marine energy developers for optimizing farm layouts. A detailed understanding of wake deflection and propagation by a yawed turbine is crucial, as, with this knowledge, the wake can be steered away from the downstream turbine. Wake path can be ascertained by tracking the center of the wake and is expected to meander both horizontally and vertically. Several methods are used to determine the center of the wake, most common of which are Gaussian-like fit, Center of mass, and mean available specific power. The variability in these definitions acts as a source of uncertainty in evaluating the wake center at downstream locations. In this paper, we aim to discuss the various methods and evaluate the usefulness of each technique based on the fidelity of the data set that is available. To this effect, we will use results from a three-dimensional transient computational fluid dynamics analysis for a tidal turbine subjected to 0°, -15° and +15° yaw cases. Change in wake shape was observed for γ ≠ 0° yaw cases, where the wake adapts an elliptical shape as it propagates downstream. The center of the mass technique is considered to be the best center of wake estimation technique as it takes into account change in wake shape for yawed flows. 

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2. Tidal current turbine in a non-homogeneous turbulent inflow: performance and near wake statistics

   Vinod, Ashwin; Banerjee, Arindam (September 2019, 13th European Wave and Tidal Energy Conference, Napoli, Italy)

   In light of the 2018 special report on climate change compiled by the United Nations, there is a renewed urgency to the rapid adoption of renewable energy technologies. A key roadblock to the large-scale/commercial conversion of tidal energy is the question concerning the operational efficiency of existing technologies in the non-homogeneous, turbulent and corrosive marine environment. A thorough understanding of the aforementioned aspects of full-scale deployment is vital in developing robust and cost-effective turbine designs and farm layouts. The current experimental work at Lehigh University aims to better the understanding of turbine performance and near-wake statistics in homogeneous and non-homogeneous turbulent flows, similar to actual marine conditions. A 1:20 laboratory scale tidal turbine model with a rotor diameter of 0.28m is used in the experiments and an active grid type turbulence generator, designed in-house, is employed to generate both homogeneous and non-homogeneous turbulent inflow conditions. To the knowledge of the authors, this is the first experimental study to explore the effects of non-homogeneous inflow turbulence on tidal turbines. From the data collected it was observed that the non-homogeneous inflow condition led to a considerable drop (15-20%) in the measured thrust coefficient. They also resulted in larger torque and thrust fluctuations on the rotor (~40% under the tested conditions). The effect of inflow non-homogeneity was evident in the asymmetric near-wake characteristics as well. Turbulence intensity and Reynolds stresses measured in the wake of the rotor were found to adapt quicker to inflow non-homogeneity than the wake velocity deficit and integral length scales. 

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3. Investigation of far-wake models coupled with yaw-induction control for power optimization

   https://doi.org/10.1088/1742-6596/2767/9/092103  

   Heck, Kirby S; Liew, Jaime; Howland, Michael F (June 2024, Journal of Physics: Conference Series)

   Combined wake steering and induction control is a promising strategy for increasing collective wind farm power production over standard turbine control. However, computationally efficient models for predicting optimal control set points still need to be tested against high-fidelity simulations, particularly in regimes of high rotor thrust. In this study, large eddy simulations (LES) are used to investigate a two-turbine array using actuator disk modeling in conventionally neutral atmospheric conditions. The thrust coefficient and yaw-misalignment angle are independently prescribed to the upwind turbine in each simulation while downwind turbine operation is fixed. Analyzing the LES velocity fields shows that near-wake length decreases and wake recovery rate increases with increasing thrust. We model the wake behavior with a physics-based near-wake and induction model coupled with a Gaussian far-wake model. The near-wake model predicts the turbine thrust and power depending on the wake steering and induction control set point. The initial wake velocities predicted by the near-wake model are validated against LES data, and a calibrated far-wake model is used to estimate the power maximizing control set point and power gain. Both model-predicted and LES optimal set points exhibit increases in yaw angle and thrust coefficient for the leading turbine relative to standard control. The model-optimal set point predicts a power gain of 18.1% while the LES optimal set point results in a power gain of 20.7%. In contrast, using a tuned cosine model for the power-yaw relationship results in a set point with a lower magnitude of yaw, a thrust coefficient lower than in standard control, and predicts a power gain of 13.7%. Using the physics-based, model-predicted set points in LES results in a power within 1.5% of optimal, showing potential for joint yaw-induction control as a method for predictably increasing wind farm power output. 

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4. On Blockage Effects for a Tidal Turbine in Free Surface Proximity

   https://doi.org/10.3390/en12173325  

   Kolekar, Nitin; Vinod, Ashwin; Banerjee, Arindam (September 2019, Energies)

   Experiments with a three-bladed, constant chord tidal turbine were undertaken to understand the influence of free surface proximity on blockage effects and near-wake flow field. The turbine was placed at various depths as rotational speeds were varied; thrust and torque data were acquired through a submerged sensor. Blockage effects were quantified in terms of changes in power coefficient and were found to be dependent on tip speed ratio and free surface to blade tip clearance. Flow acceleration near turbine rotation plane was attributed to blockage offered by the rotor, wake, and free surface deformation. In addition, particle image velocimetry was carried out in the turbine near-wake using time- and phase-averaged techniques to understand the mechanism responsible for the variation of power coefficient with rotational speed and free surface proximity. Slower wake propagation for higher rotational velocities and increased asymmetry in the wake with increasing free surface proximity was observed. Improved performance at high rotational speed was attributed to enhanced wake blockage, and performance enhancement with free surface proximity was due to the additional blockage effects caused by the free surface deformation. Proper orthogonal decomposition analysis revealed a downward moving wake for the turbine placed in near free surface proximity. 

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5. Enhanced Modeling of Joint Yaw and Axial Induction Control Using Blade Element Momentum Methods

   https://doi.org/10.1088/1742-6596/2767/3/032018  

   Liew, Jaime; Heck, Kirby; Howland, Michael F (June 2024, Journal of Physics: Conference Series)

   Wind turbine control via concurrent yaw misalignment and axial induction control has demonstrated potential for improving wind farm power output and mitigating structural loads. However, the complex aerodynamic interplay between these two effects requires deeper investigation. This study presents a modified blade element momentum (BEM) model that matches rotor-averaged quantities to an actuator disk model of yawed rotor induction, enabling analysis of joint yaw-induction control using realistic turbine control inputs. The BEM approach reveals that common torque control strategies such as K−Ω^2 exhibit sub-optimal performance under yawed conditions. Notably, the power-yaw and thrust-yaw sensitivities vary significantly depending on the chosen control strategy, contrary to common modeling assumptions. In the context of wind farm control, employing induction control which minimizes the thrust coefficient proves most effective at reducing wake strength for a given power output across all yaw angles. Results indicate that while yaw control deflects wakes effectively, induction control more directly influences wake velocity magnitude, underscoring their complementary effects. This study advances a fundamental understanding of turbine aerodynamic responses in yawed operation and sets the stage for modeling joint yaw and induction control in wind farms. 

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